The Sun - Size and Mass. Masses. Note: Most of solar system mass is in. Radii } } Densities
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1 The Sun - Size and Mass Masses Note: Most of solar system mass is in Radii } } Densities 1
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4 Sun - Composition Consolmagno & Schaefer 4
5 5
6 From Wood, in Beatty & Chaikin 6
7 The missing elements form gases At inner solar system temperatures: O + 2H H 2 O C + 4H CH 4 N + 3H NH 3 Swept away by solar winds Remaining: minerals, metals - rocks & grains Rotation thin disk, accumulation planets edge-on view of orbiting grains 7
8 The Sun as a Star Is the Sun a typical star? What characterizes typical stars? Possible observations: Brightness (energy output rate) Mass Surface temperature (color) Composition (elements in atmosphere) Rotation rate Easiest to measure: Brightness (chief difficulty is distance correction) Surface temperature Procedure: Measure L = luminosity = energy/time Measure Temission (from blue/red ratio) Make scatter plot L vs. T e, for lots of stars Look for patterns in the scatter plot Such a scatter plot is called a Hertzsprung-Russell diagram. Comment: It is best to do this for star clusters because the stars are then all at the same distance. 8
9 9
10 H-R diagram, showing the locations of the brightest stars. 10
11 H-R diagram for a typical Open Cluster. = Sun H-R diagram for a typical Globular Cluster. 11
12 Hertzsprung-Russell Diagram Stars are strung out along the main sequence according to their masses. Small mass low luminosity, low surface temperature Sun is typical mid-life MS star, but a bit smaller than average. Principal other groupings in the H. R. diagram: Red giants: large stars, recently left MS, He cores Horizontal branch: post-ms stars burning helium. White dwarfs: small old stars, depleted in hydrogen Summary: Mass and age are principal factors determining the properties of a star. Composition, rotation, or other factors are secondary. 12
13 Solar Internal Conditions Few direct observations - need reasoning based on physical principles - but conditions are extreme.risky Strategy: Know density is low & temperature high assume ideal gas state Then pressure p = R T /, where is mean molecular weight Know total mass pressure can be estimated from gravity Then knowing p, internal temperature if is known. 13
14 Solar Internal Pressure Gravitational force M 1 M 2 Apply to two halves of Sun to make rough estimate: r Each side has 1/2 solar mass Use 1/2 solar radius to estimate distance pressure = force/area 14
15 Solar Internal Temperature Use ideal gas assumption, p = RT Where Note: We use here the meteorological convention of writing R = R /, where R is the universal gas constant and is the mean atomic weight. This assumes atomic weight = 0.5, half protons, half electrons. Agrees with theoretical estimates of the requirement for nuclear fusion. 15
16 What Determines Brightness? On main sequence, temperature drops from 15 x 10 6 K at core of star to much smaller values near edge. Temperature gradient diffusion of radiative energy out. This radiative diffusion rate determines the luminosity L. Surface temperature adjusts so that L radiates to space. where = Stefan-Boltzmann constant = 5.67 x 10-8 W m -2 K -4. It turns out that L is proportional (approximately) to M 4. (Which stars have longest main sequence lifetimes, high mass or low mass?) 16
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18 n 18
19 Interior: Dependence on Radius Over a star s lifetime the mass usually stays constant but the radius will change. A star starts its life as a diffuse cloud, and then shrinks. An estimate of internal T gives Temperature varies inversely with radius. In the diagram, central temperature increases toward the right. Gravity intensifies for a compact object pressure increase temperature increase Gravitational energy release (a) higher central T and (b) loss of heat to space by radiation. When nuclear burning ignition temperature (about 15 x 10 6 K) is reached, shrinking stops and main sequence is reached. From equation, main sequence large mass large radius. 19
20 Comments Fusion of H He stage (main sequence) for 1M star lasts ~10 billion yrs; Sun is ~ half way through. Sun appears to be a stable hydrogen burner. After H He, we have He C plus burning in shells. Complicated structure. red giants, nove & supernovae (more massive stars only). return of material to interstellar medium Neutrino counters can test nucleosynthesis reaction theories Example of Virial Theorem 20
21 Billions of years from now the Sun will grow enormously in size and luminosity. Note the different time scales, expanded near the end of the Sun s life to show relatively rapid changes. The orbits of the planets enlarge due to mass loss from the Sun. By the time our star becomes a white dwarf, it will have only 0.51 to 0.58 of its present mass. 21
22 Sun - Summary 1. The Sun is an ordinary main sequence star, slightly smaller than average 2. Its age is about 4.5 billion years, about half of its main sequence lifetime. 3. Its luminosity is 3.9 x J s -1 and the solar flux at the Earth s mean distance is W m The solar radius is 7 x 10 8 m. Its emission temperature is about 5780 K. 5. The surface composition of the Sun is very similar to that of primitive meteorites, except for the most volatile species (H, He, Ne, Ar, C, N, O) 6. Over its lifetime on the main sequence, the solar luminosity is predicted by stellar structure theory to increase by 15 or 20%. 7. In another 7-8 Gyr, the Sun will expand into a red giant, first roasting and then perhaps engulfing the terrestrial planets. 22
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